Mathematical Modeling of Protein Complexes

Tatiana Koshlan graduated from St. Petersburg State University, the department of Molecular Biophysics and Physics of Polymers. She is Master of Science in the field of biophysics. Now she is a post-graduate student at the department of Photonics, St. Petersburg State University. Her interdisciplinary research is in the field of biological and physical sciences. Her research is devoted to studying the interaction of biological molecules by physical methods, using mathematical tools to develop new technology and software with the ability to perform systematic measurements of various data sets of biological interactions. Kirill Kulikov has been a full professor since 2014 at Peter the Great St. Petersburg Polytechnical University, Institute of Applied Mathematics and Mechanics, Department of Higher Mathematics. He received his Ph.D. in Physics and Mathematics with «Mathematical Modeling of the Optical Properties of Multilayer Biological Systems and Structures in their Heterogeneous Conjugation» (2004). He has habilitation at the State Polytechnical University (Great St. Petersburg Polytechnical University) of St. Petersburg, Russia (Doctor Science in Physics and Mathematics). His Doctor of Science thesis title was «Analytical models of interaction of laser radiation with complex heterogeneous biological tissues» (2014). His research interests are theory diffraction theory, electrodynamics, physics of lasers, tissue optical methods of mathematical modeling in biological tissue optics and numerical method, biophysics.

Introduction.- Physical methods for studying proteins.- Physical properties of amino acids and proteins.- Selection of a biological objects.- Mathematical simulation of complex formation of protein molecules allowing for their domain structure.- Mathematical modeling of  histone dimers  formation in vitro with solutions of different ionic strength in the presence of monovalent salts.- Mathematical modeling  of the temperature  effect  on binding of monomeric proteins  in aqueous solutions by  example on histones  H2A, H2B, H3 and H4.- Mathematical modeling of the temperature  effect on binding of  different sites of protein BCL-XL  in aqueous solutions.- Mathematical modeling of the phosphorylation effect on the nature formation of biological complexes P53-MDM2 and P53-P300.

"It is to be expected that the monograph will be of interest to researchers in the field of applied proteomics who possess an aptitude for mathematical modelling and numerical simulation." (Nikola Popovic, zbMATH 1470.92004, 2021)

“It is to be expected that the monograph will be of interest to researchers in the field of applied proteomics who possess an aptitude for mathematical modelling and numerical simulation.” (Nikola Popovic, zbMATH 1470.92004, 2021)